Missing the Point in Noncommutative Geometry

Total Page:16

File Type:pdf, Size:1020Kb

Missing the Point in Noncommutative Geometry Missing the point in noncommutative geometry Nick Huggetta∗, Fedele Lizzib,c,d†, and Tushar Menone‡ June 20, 2021 a Department of Philosophy, University of Illinois at Chicago Chicago, IL, United States b Dipartimento di Fisica “Ettore Pancini”, Università di Napoli Federico II, Napoli, Italy c INFN, Sezione di Napoli, Italy d Departament de Física Quàntica i Astrofìsica and Institut de Cìences del Cosmos (ICCUB), Universitat de Barcelona, Barcelona, Spain e Faculty of Philosophy, University of Cambridge, Cambridge, United Kingdom Abstract Noncommutative geometries generalize standard smooth geometries, parametriz- ing the noncommutativity of dimensions with a fundamental quantity with the di- mensions of area. The question arises then of whether the concept of a region smaller than the scale - and ultimately the concept of a point - makes sense in such a theory. We argue that it does not, in two interrelated ways. In the context of Connes’ spectral triple approach, we show that arbitrarily small regions are not definable in the formal sense. While in the scalar field Moyal-Weyl approach, we show that they cannot be given an operational definition. We conclude that points do not exist in such geome- arXiv:2006.13035v2 [physics.hist-ph] 11 Dec 2020 tries. We therefore investigate (a) the metaphysics of such a geometry, and (b) how the appearance of smooth manifold might be recovered as an approximation to a fundamental noncommutative geometry. ∗[email protected][email protected][email protected] 1 Contents Contents 1 Introduction2 2 Spectral triples4 2.1 Meaning and definition . .5 2.2 The spectral approach . .7 3 Operationalism 15 3.1 The tempered operationalist approach to points . 15 3.1.1 Classical space . 16 3.1.2 Quantum kinematics . 17 3.2 Noncommutative space . 18 4 Ontology 21 5 Recovering space from NCG 25 5.1 The Moyal and Weyl representations . 25 5.2 Finding Spacetime . 28 5.3 Empirical coherence and physical salience . 32 6 Conclusion 34 1 Introduction In the vast landscape of contemporary theoretical physics, few research programmes come as close to engaging, as a matter of course, with traditional metaphysics as quantum gravity research programmes do. The two theoretical edifices that these programmes aim to unify (or replace)— quantum theory and relativistic gravitation theory—have been notoriously uncooperative with attempts at unification. It is not clear precisely which aspect of these theories is to blame, and what aspects ought to be held onto in future theories. Consequently, we are led back to traditional questions in the metaphysics of space and time. Questions like: what is the nature of space(time)? Are space(time) points fundamental? Is space(time) discrete? In this paper, we discuss a particular approach to the metaphysics of discrete space suggested by one popular family of approaches to quantum geometry that go under the name of noncommu- tative geometries. From a philosophical perspective, attention to noncommutative field theories is valuable, because these theories allow us to embed our extant, well-confirmed physical theories in a broader logical landscape. Doing so allows us to unearth a number of tacit assumptions in 2 x1 Introduction our current physical theories that might otherwise have been invisible, or appeared as matters of necessity. Our goal, therefore, is to introduce noncommutative geometry to a wider philosophical au- dience, by discussing three metaphysical puzzles about the nature of space and, in particular, indeterminacy of location to which these geometries give rise. We understand ‘indeterminacy of location’ as referring to situations in which, for whatever reason, nature does not ascribe to a body a determinate a matter of fact about its spatial location below a particular scale. The first puzzle, accordingly, is to characterise this particular brand of metaphysical indeterminacy. This leads to the second puzzle of how one ought to think about the ontology of a theory that is based on a noncommutative geometry. The final puzzle is to account for our experience of spacetime as, at least approximately, being described by a commutative geometry. There is a family of approaches to modelling indeterminacy in quantum mechanics mentioned according to which, if quantum mechanics is true, then particular facts about the world are ‘unsettled’—we can pose questions about the values of certain properties of systems such as, say, the x and the y components of spin, but nature itself does not determine the answers to such questions. Here, we focus on the subspecies of these approaches dubbed ‘supervaluationist’ (see e.g. [11, 12]).1 We refer to this approach as modelling indeterminacy as underdetermination: one considers various precisifications of the models of the physical system, and then models indeterminacy as the underdetermination of which of the precisifications truly represents the world. Some sorts of quantum indeterminacy can plausibly be modelled as underdetermination, because ordinary quantum mechanics presupposes a continuous manifold of spatial points structured by some geometric relations (in non-relativistic quantum mechanics, these are the relations that constitute Galilean spacetime). Each precisification is itself antecedently mean- ingful, on the basis of a localisability thesis that we defend below. Noncommutative geometry, on our interpretation, does not have the resources to make meaningful claims about localisabil- ity below a certain magnitude. We therefore argue that the indeterminacy that results from a noncommutative approach to spatial geometry, as suggested by noncommutative geometric approaches to quantum geometry is of a different kind from what the supervaluationists consider. We call this indeterminacy as meaninglessness. In this paper, we cash out ‘meaninglessness’ in two distinct ways, depending on the approach to NCG: (i)§2 presents Alain Connes’ spectral triple generalisation of Riemannian geometry, and characterises meaninglessness as undefinability; (ii)§3 presents a concrete representation of quantum theories in noncommutative space, and characterises meaningless as non-operationalisability. We then invoke an Occamist norm to link these semantic claims to our preferred metaphysical picture on which we deny the existence of 1Since the ‘determinables-based’ approaches (primarily associated with Wilson and collaborators, [42, 8]) also presuppose a topological manifold structure on the domain of discourse, the criticism we offer in this paper also targets the determinables-based approach. However, for dialectical clarity, we choose to focus only on the supervaluationist approaches. 3 x2 Spectral triples spacetime points.2 Having established our argument for a fundamental metaphysics that eschews the concept of arbitrary localisability, we discuss some alternative views of the ontology of a noncommutative field theory in §4. One thing all of these proposals agree on is that the elements of the relevant noncommutative algebra should be treated as fundamental. The picture of a field as an ascription of properties to points (supplemented with some story, kinematical or dynamical, about how those points are related to each other) is untenable. While fields-first proposals have been in the philosophical literature for decades (Earman discussed so-called Leibniz algebras at least as far back as 1977 [18]), they have been presented as alternatives to standard ontologies for commutative theories like general relativity. In noncommutative field theories, fields-first interpretations are the only game in town. In §5, we go on to examine a proposal for the recovery, from a noncommutative underlying geometry, of physical spacetime that is at least approximately commutative. In particular, we discuss a proposal that relies on structural features of quantum field theories to allow us, at least in some restricted but nonetheless physically salient circumstances, to recover a geometry that is approximately Minkowskian. The mismatch between the manifest and scientific images of space is an especially acute problem in the case of a theory with a putatively non-spatiotemporal fundamental ontology. This is because all evidence for a theory is ultimately given in terms of spatiotemporal data. In recovering the manifest image from NCG, at least in a restricted context, we counter the possibility that NCG is empirically incoherent, to use a term introduced by Barrett [2] to describe theories whose truth undermines our justification for believing in their truth. 2 Spectral triples A standard move in contemporary philosophy of spacetime is to model a spacetime theory as con- sisting of a smooth (i.e. infinitely differentiable), second countable, Hausdorff manifold on which are defined some tensor fields which encode spatial and temporal relations (in relativity theory, a Lorentzian metric tensor field) and some other tensor (or spinorial tensor) fields representing a matter distribution. The elements of the smooth manifold are typically treated as constituting the domain of discourse, call it M, of the theory; these elements, (commonly referred to as the ‘spacetime points’), are considered to be part of the fundamental, non-derived, non-emergent ontology of the theory. We take such a structure as the starting point for our discussion, using it to define a notion of localisability in §2.1. However, as we show in §2.2, such localisability is undefinable below a certain distance in the noncommutative space proposed by Alain Connes. In this sense, such distances are unphysical, and with them point
Recommended publications
  • Noncommutative Geometry and the Spectral Model of Space-Time
    S´eminaire Poincar´eX (2007) 179 – 202 S´eminaire Poincar´e Noncommutative geometry and the spectral model of space-time Alain Connes IHES´ 35, route de Chartres 91440 Bures-sur-Yvette - France Abstract. This is a report on our joint work with A. Chamseddine and M. Marcolli. This essay gives a short introduction to a potential application in physics of a new type of geometry based on spectral considerations which is convenient when dealing with noncommutative spaces i.e. spaces in which the simplifying rule of commutativity is no longer applied to the coordinates. Starting from the phenomenological Lagrangian of gravity coupled with matter one infers, using the spectral action principle, that space-time admits a fine structure which is a subtle mixture of the usual 4-dimensional continuum with a finite discrete structure F . Under the (unrealistic) hypothesis that this structure remains valid (i.e. one does not have any “hyperfine” modification) until the unification scale, one obtains a number of predictions whose approximate validity is a basic test of the approach. 1 Background Our knowledge of space-time can be summarized by the transition from the flat Minkowski metric ds2 = − dt2 + dx2 + dy2 + dz2 (1) to the Lorentzian metric 2 µ ν ds = gµν dx dx (2) of curved space-time with gravitational potential gµν . The basic principle is the Einstein-Hilbert action principle Z 1 √ 4 SE[ gµν ] = r g d x (3) G M where r is the scalar curvature of the space-time manifold M. This action principle only accounts for the gravitational forces and a full account of the forces observed so far requires the addition of new fields, and of corresponding new terms SSM in the action, which constitute the Standard Model so that the total action is of the form, S = SE + SSM .
    [Show full text]
  • Space and Time Dimensions of Algebras With
    Space and time dimensions of algebras with applications to Lorentzian noncommutative geometry and quantum electrodynamics Nadir Bizi, Christian Brouder, Fabien Besnard To cite this version: Nadir Bizi, Christian Brouder, Fabien Besnard. Space and time dimensions of algebras with appli- cations to Lorentzian noncommutative geometry and quantum electrodynamics. Journal of Mathe- matical Physics, American Institute of Physics (AIP), 2018, 59 (6), pp.062303. 10.1063/1.4986228. hal-01398231v2 HAL Id: hal-01398231 https://hal.archives-ouvertes.fr/hal-01398231v2 Submitted on 16 May 2019 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Space and time dimensions of algebras with application to Lorentzian noncommutative geometry and quantum electrodynamics Nadir Bizi, Christian Brouder, and Fabien Besnard Citation: Journal of Mathematical Physics 59, 062303 (2018); doi: 10.1063/1.5010424 View online: https://doi.org/10.1063/1.5010424 View Table of Contents: http://aip.scitation.org/toc/jmp/59/6 Published by the American Institute of Physics Articles you may
    [Show full text]
  • Noncommutative Geometry and Flavour Mixing
    Noncommutative geometry and flavour mixing prepared by Jose´ M. Gracia-Bond´ıa Department of Theoretical Physics Universidad de Zaragoza, 50009 Zaragoza, Spain October 22, 2013 1 Introduction: the universality problem “The origin of the quark and lepton masses is shrouded in mystery” [1]. Some thirty years ago, attempts to solve the enigma based on textures of the quark mass matrices, purposedly reflecting mass hierarchies and “nearest-neighbour” interactions, were very popular. Now, in the late eighties, Branco, Lavoura and Mota [2] showed that, within the SM, the zero pattern 0a b 01 @c 0 dA; (1) 0 e 0 a central ingredient of Fritzsch’s well-known Ansatz for the mass matrices, is devoid of any particular physical meaning. (The top quark is above on top.) Although perhaps this was not immediately clear at the time, paper [2] marked a water- shed in the theory of flavour mixing. In algebraic terms, it establishes that the linear subspace of matrices of the form (1) is universal for the group action of unitaries effecting chiral basis transformations, that respect the charged-current term of the Lagrangian. That is, any mass matrix can be transformed to that form without modifying the corresponding CKM matrix. To put matters in perspective, consider the unitary group acting by similarity on three-by- three matrices. The classical triangularization theorem by Schur ensures that the zero patterns 0a 0 01 0a b c1 @b c 0A; @0 d eA (2) d e f 0 0 f are universal in this sense. However, proof that the zero pattern 0a b 01 @0 c dA e 0 f 1 is universal was published [3] just three years ago! (Any off-diagonal n(n−1)=2 zero pattern with zeroes at some (i j) and no zeroes at the matching ( ji), is universal in this sense, for complex n × n matrices.) Fast-forwarding to the present time, notwithstanding steady experimental progress [4] and a huge amount of theoretical work by many authors, we cannot be sure of being any closer to solving the “Meroitic” problem [5] of divining the spectrum behind the known data.
    [Show full text]
  • Noncommutative Stacks
    Noncommutative Stacks Introduction One of the purposes of this work is to introduce a noncommutative analogue of Artin’s and Deligne-Mumford algebraic stacks in the most natural and sufficiently general way. We start with quasi-coherent modules on fibered categories, then define stacks and prestacks. We define formally smooth, formally unramified, and formally ´etale cartesian functors. This provides us with enough tools to extend to stacks the glueing formalism we developed in [KR3] for presheaves and sheaves of sets. Quasi-coherent presheaves and sheaves on a fibered category. Quasi-coherent sheaves on geometric (i.e. locally ringed topological) spaces were in- troduced in fifties. The notion of quasi-coherent modules was extended in an obvious way to ringed sites and toposes at the moment the latter appeared (in SGA), but it was not used much in this generality. Recently, the subject was revisited by D. Orlov in his work on quasi-coherent sheaves in commutative an noncommutative geometry [Or] and by G. Laumon an L. Moret-Bailly in their book on algebraic stacks [LM-B]. Slightly generalizing [R4], we associate with any functor F (regarded as a category over a category) the category of ’quasi-coherent presheaves’ on F (otherwise called ’quasi- coherent presheaves of modules’ or simply ’quasi-coherent modules’) and study some basic properties of this correspondence in the case when the functor defines a fibered category. Imitating [Gir], we define the quasi-topology of 1-descent (or simply ’descent’) and the quasi-topology of 2-descent (or ’effective descent’) on the base of a fibered category (i.e.
    [Show full text]
  • Noncommutative Geometry, the Spectral Standpoint Arxiv
    Noncommutative Geometry, the spectral standpoint Alain Connes October 24, 2019 In memory of John Roe, and in recognition of his pioneering achievements in coarse geometry and index theory. Abstract We update our Year 2000 account of Noncommutative Geometry in [68]. There, we de- scribed the following basic features of the subject: I The natural “time evolution" that makes noncommutative spaces dynamical from their measure theory. I The new calculus which is based on operators in Hilbert space, the Dixmier trace and the Wodzicki residue. I The spectral geometric paradigm which extends the Riemannian paradigm to the non- commutative world and gives a new tool to understand the forces of nature as pure gravity on a more involved geometric structure mixture of continuum with the discrete. I The key examples such as duals of discrete groups, leaf spaces of foliations and de- formations of ordinary spaces, which showed, very early on, that the relevance of this new paradigm was going far beyond the framework of Riemannian geometry. Here, we shall report1 on the following highlights from among the many discoveries made since 2000: 1. The interplay of the geometry with the modular theory for noncommutative tori. 2. Great advances on the Baum-Connes conjecture, on coarse geometry and on higher in- dex theory. 3. The geometrization of the pseudo-differential calculi using smooth groupoids. 4. The development of Hopf cyclic cohomology. 5. The increasing role of topological cyclic homology in number theory, and of the lambda arXiv:1910.10407v1 [math.QA] 23 Oct 2019 operations in archimedean cohomology. 6. The understanding of the renormalization group as a motivic Galois group.
    [Show full text]
  • On the Generalized Non-Commutative Sphere and Their K-Theory
    Global Journal of Pure and Applied Mathematics. ISSN 0973-1768 Volume 12, Number 2 (2016), pp. 1325-1335 © Research India Publications http://www.ripublication.com On the generalized non-commutative sphere and their K-theory Saleh Omran Taif University, Faculty of Science, Taif , KSA South valley university, Faculty of science, Math. Dep. Qena , Egypt. Abstract In the work we follow the work of J.Cuntz, he associate a universal C* - algebra to every locally finite flag simplicial complex. In this article we define * nc a universal C -algebra S3 , associated to the 3 -dimensional noncommutative sphere. We analyze the topological information of the noncommutative sphere by using it’s skeleton filtration Ik )( . We examine the nc K -theory of the quotient 3 /IS k , and I k for such kk 7, . Keywords: Universal C* -algebra , Noncommutative sphere, K -theory of C* -algebra. 2000 AMS : 19 K 46. 1. Introduction Noncommutative 3 -sphere play an important role in the non commutative geometry which introduced by Allain Connes [4] .In noncommutative geometry, the set of points in the space are replaced by the set of continuous functions on the space. In fact noncommutative geometry change our point of view from the topological space itself to the functions on the space ( The algebra of functions on the space). Indeed, the main idea was noticed first by Gelfand-Niemark [8] they were give an important theorem which state that: any commutative C* -algebra is isomorphic of the continuous functions of a compact space, namely the space of characters of the algebra. More generally any C* -algebra ( commutative or not) is isomorphic to a closed subalgebra of the algebra of bounded operators on a Hilbert space.
    [Show full text]
  • What Is Noncommutative Geometry ? How a Geometry Can Be Commutative and Why Mine Is Not
    What is Noncommutative Geometry ? How a geometry can be commutative and why mine is not Alessandro Rubin Junior Math Days 2019/20 SISSA - Scuola Internazionale Superiore di Studi Avanzati This means that the algebra C∞(M) contains enough information to codify the whole geometry of the manifold: 1. Vector fields: linear derivations of C∞(M) 2. Differential 1-forms: C∞(M)-linear forms on vector fields 3. ... Question Do we really need a manifold’s points to study it ? Do we really use the commutativity of the algebra C∞(M) to define the aforementioned objects ? Doing Geometry Without a Geometric Space Theorem Two smooth manifolds M, N are diffeomorphic if and only if their algebras of smooth functions C∞(M) and C∞(N) are isomorphic. 1/41 Question Do we really need a manifold’s points to study it ? Do we really use the commutativity of the algebra C∞(M) to define the aforementioned objects ? Doing Geometry Without a Geometric Space Theorem Two smooth manifolds M, N are diffeomorphic if and only if their algebras of smooth functions C∞(M) and C∞(N) are isomorphic. This means that the algebra C∞(M) contains enough information to codify the whole geometry of the manifold: 1. Vector fields: linear derivations of C∞(M) 2. Differential 1-forms: C∞(M)-linear forms on vector fields 3. ... 1/41 Do we really use the commutativity of the algebra C∞(M) to define the aforementioned objects ? Doing Geometry Without a Geometric Space Theorem Two smooth manifolds M, N are diffeomorphic if and only if their algebras of smooth functions C∞(M) and C∞(N) are isomorphic.
    [Show full text]
  • Quantum Information Hidden in Quantum Fields
    Preprints (www.preprints.org) | NOT PEER-REVIEWED | Posted: 21 July 2020 Peer-reviewed version available at Quantum Reports 2020, 2, 33; doi:10.3390/quantum2030033 Article Quantum Information Hidden in Quantum Fields Paola Zizzi Department of Brain and Behavioural Sciences, University of Pavia, Piazza Botta, 11, 27100 Pavia, Italy; [email protected]; Phone: +39 3475300467 Abstract: We investigate a possible reduction mechanism from (bosonic) Quantum Field Theory (QFT) to Quantum Mechanics (QM), in a way that could explain the apparent loss of degrees of freedom of the original theory in terms of quantum information in the reduced one. This reduction mechanism consists mainly in performing an ansatz on the boson field operator, which takes into account quantum foam and non-commutative geometry. Through the reduction mechanism, QFT reveals its hidden internal structure, which is a quantum network of maximally entangled multipartite states. In the end, a new approach to the quantum simulation of QFT is proposed through the use of QFT's internal quantum network Keywords: Quantum field theory; Quantum information; Quantum foam; Non-commutative geometry; Quantum simulation 1. Introduction Until the 1950s, the common opinion was that quantum field theory (QFT) was just quantum mechanics (QM) plus special relativity. But that is not the whole story, as well described in [1] [2]. There, the authors mainly say that the fact that QFT was "discovered" in an attempt to extend QM to the relativistic regime is only historically accidental. Indeed, QFT is necessary and applied also in the study of condensed matter, e.g. in the case of superconductivity, superfluidity, ferromagnetism, etc.
    [Show full text]
  • [Math-Ph] 28 Aug 2006 an Introduction to Noncommutative Geometry
    An Introduction to Noncommutative Geometry Joseph C. V´arilly Universidad de Costa Rica, 2060 San Jos´e, Costa Rica 28 April 2006 Abstract The lecture notes of this course at the EMS Summer School on Noncommutative Geometry and Applications in September, 1997 are now published by the EMS. Here are the contents, preface and updated bibliography from the published book. Contents 1 Commutative Geometry from the Noncommutative Point of View 1.1 The Gelfand–Na˘ımark cofunctors 1.2 The Γ functor 1.3 Hermitian metrics and spinc structures 1.4 The Dirac operator and the distance formula 2 Spectral Triples on the Riemann Sphere 2.1 Line bundles and the spinor bundle 2.2 The Dirac operator on the sphere S2 2.3 Spinor harmonics and the spectrum of D/ 2.4 Twisted spinor modules arXiv:physics/9709045v2 [math-ph] 28 Aug 2006 2.5 A reducible spectral triple 3 Real Spectral Triples: the Axiomatic Foundation 3.1 The data set 3.2 Infinitesimals and dimension 3.3 The first-order condition 3.4 Smoothness of the algebra 3.5 Hochschild cycles and orientation 3.6 Finiteness of the K-cycle 1 3.7 Poincar´eduality and K-theory 3.8 The real structure 4 Geometries on the Noncommutative Torus 4.1 Algebras of Weyl operators 4.2 The algebra of the noncommutative torus 4.3 The skeleton of the noncommutative torus 4.4 A family of spin geometries on the torus 5 The Noncommutative Integral 5.1 The Dixmier trace on infinitesimals 5.2 Pseudodifferential operators 5.3 The Wodzicki residue 5.4 The trace theorem 5.5 Integrals and zeta residues 6 Quantization and the Tangent Groupoid
    [Show full text]
  • Noncommutative Geometry Andrew Lesniewski
    lesniewski.qxp 3/25/98 9:11 AM Page 800 Noncommutative Geometry Andrew Lesniewski Noncommutative Spaces is a locally compact space, and A C0(M), where ' 0(M) denotes the C∗ -algebra of continuous It was noticed a long time ago that various prop- C erties of sets of points can be restated in terms functions on M vanishing at infinity. of properties of certain commutative rings of Recall that a C∗-algebra is an algebra over C, functions over those sets. In particular, this ob- equipped with an involutive operation and a servation proved to be extremely fruitful in al- ∗ norm , which satisfies the condition gebraic geometry and has led to tremendous k·k SS = S 2. In other words, the category of progress in this subject over the past few k ∗k k k decades. In these developments the concept of locally compact spaces is equivalent to the cat- a point in a space is secondary and overshadowed egory of abelian C∗ -algebras. The points of a by the algebraic properties of the (sheaves of) topological space can be characterized in purely rings of functions on those spaces. algebraic terms as the maximal ideals of an al- This idea also underlies noncommutative gebra of functions on the space. geometry, a new direction in mathematics initi- Another important source of inspiration for ated by the French mathematician Alain Connes noncommutative geometry is quantum physics. and outlined in his recent book [3]. In noncom- It has been known since the heroic days of quan- mutative geometry one goes one step further: it tum mechanics (Heisenberg, Born, Jordan, is no longer required that the algebra of func- Schrödinger, Dirac, von Neumann, … ) that or- tions be commutative! Furthermore, while alge- dinary concepts of classical mechanics and sym- braic geometry did not entirely rid itself of the plectic geometry do not apply to the subatomic concept of a point, noncommutative geometry world.
    [Show full text]
  • Contemporary Mathematics 365
    CONTEMPORARY MATHEMATICS 365 Operator Algebras, Quantization, and Noncommutative Geometry A Centennial Celebration Honoring John von Neumann and Marshall H. Stone AMS Special Session on Operator Algebras, Quantization, and Noncommutative Geometry: A Centennial Celebration Honoring John von Neumann and Marshall H. Stone January 15-16, 2003 Baltimore, Maryland Robert S. Doran Richard V. Kadison Editors http://dx.doi.org/10.1090/conm/365 Dedicated to the memory of John von Neumann and Marshall H. Stone CoNTEMPORARY MATHEMATICS 365 Operator Algebras, Quantization, and Noncommutative Geometry A Centennial Celebration Honoring John von Neumann and Marshall H. Stone AMS Special Session on Operator Algebras, Quantization, and Noncommutative Geometry: A Centennial Celebration Honoring John von Neumann and Marshall H. Stone January 15-16,2003 Baltimore, Maryland Robert S. Doran Richard V. Kadison Editors American Mathematical Society Providence, Rhode Island Editorial Board Dennis DeTurck, managing editor Andreas Blass Andy R. Magid Michael Vogelius This volume contains the proceedings of an AMS Special Session entitled "Operator Algebras, Quantization, and Noncommutative Geometry: A Centennial Celebration Hon- oring John von Neumann and Marshall H. Stone" marking the lOOth anniversary of the birth of both von Neumann and Stone. It was held January 15-16, 2003; in Baltimore, Maryland. 2000 Mathematics Subject Classification. Primary 01A70, 19K56, 22D25, 46L05, 46L07, 46L10, 46L53, 46L65, 46L87, 58B34, 58J22,81R05. The opening paragraph of a classic paper, John von Neumann's "Die Eindeutigkeit des Schroedingerschen Operatoren", Mathematische Annalen 104 (1931), 570-578, translated in English, appears on pp. 335-336 of Jonathan Rosenberg's article "A Selective History of the Stone-von Neumann Theorem".
    [Show full text]
  • Spectral Action in Noncommutative Geometry
    Michał Eckstein, Bruno Iochum Spectral Action in Noncommutative Geometry Published as SpringerBriefs in Mathematical Physics Volume 27 https://www.springer.com/la/book/9783319947877 arXiv:1902.05306v1 [math-ph] 14 Feb 2019 Preface This book is dedicated to Alain Connes, whose work has always been a fantastic source of inspiration for us. The Least Action Principle is among the most profound laws of physics. The action — a functional of the fields relevant to a given physical system — encodes the entire dynamics. Its strength stems from its universality: The principle applies equally well in every domain of modern physics including classical mechanics, gen- eral relativity and quantum field theory. Most notably, the action is a primary tool in model-building in particle physics and cosmology. The discovery of the Least Action Principle impelled a paradigm shift in the methodology of physics. The postulates of a theory are now formulated at the level of the action, rather than the equations of motion themselves.Whereas the success of the ‘New Method’ cannot be overestimated, it raises a big question at a higher level: “Where does the action come from?” A quick look at the current theoretical efforts in cosmology and particle physics reveals an overwhelming multitude of models determined by the actions, which are postulated basing on different assumptions, beliefs, intuitions and prejudices. Clearly, it is the empirical evidence that should ultimately select the correct theory, but one cannot help the impression that our current models are only effective and an overarching principle remains concealed. A proposal for such an encompassing postulate was formulated by Ali Chamsed- dine and Alain Connes in 1996 [5].
    [Show full text]